static void lb_reserve_table_memory(struct lb_header *head)
{
/* Dynamic cbmem has already reserved the memory where the coreboot tables
* reside. Therefore, there is nothing to fix up. */
#if !CONFIG_DYNAMIC_CBMEM
struct lb_record *last_rec;
struct lb_memory *mem;
uint64_t start;
uint64_t end;
int i, entries;
last_rec = lb_last_record(head);
mem = get_lb_mem();
start = (unsigned long)head;
end = (unsigned long)last_rec;
entries = (mem->size - sizeof(*mem))/sizeof(mem->map[0]);
/* Resize the right two memory areas so this table is in
* a reserved area of memory. Everything has been carefully
* setup so that is all we need to do.
*/
for(i = 0; i < entries; i++ ) {
uint64_t map_start = unpack_lb64(mem->map[i].start);
uint64_t map_end = map_start + unpack_lb64(mem->map[i].size);
/* Does this area need to be expanded? */
if (map_end == start) {
mem->map[i].size = pack_lb64(end - map_start);
}
/* Does this area need to be contracted? */
else if (map_start == start) {
mem->map[i].start = pack_lb64(end);
mem->map[i].size = pack_lb64(map_end - end);
}
}
#endif
}
static boot_state_t bs_payload_load(void *arg)
{
void *payload;
void *entry;
timestamp_add_now(TS_LOAD_PAYLOAD);
payload = cbfs_load_payload(CBFS_DEFAULT_MEDIA,
CONFIG_CBFS_PREFIX "/payload");
if (! payload)
die("Could not find a payload\n");
entry = selfload(get_lb_mem(), payload);
if (! entry)
die("Could not load payload\n");
/* Pass the payload to the next state. */
boot_states[BS_PAYLOAD_BOOT].arg = entry;
return BS_PAYLOAD_BOOT;
}
struct lb_memory *write_tables(void)
{
unsigned long table_pointer, new_table_pointer;
#if ! CONFIG_DYNAMIC_CBMEM
if (!high_tables_base) {
printk(BIOS_ERR, "ERROR: high_tables_base is not set.\n");
}
printk(BIOS_DEBUG, "high_tables_base: %llx.\n", high_tables_base);
#endif
post_code(0x9d);
table_pointer = (unsigned long)cbmem_add(CBMEM_ID_CBTABLE,
MAX_COREBOOT_TABLE_SIZE);
if (!table_pointer) {
printk(BIOS_ERR, "Could not add CBMEM for coreboot table.\n");
return NULL;
}
new_table_pointer = write_coreboot_table(0UL, 0UL,
table_pointer, table_pointer);
if (new_table_pointer > (table_pointer + MAX_COREBOOT_TABLE_SIZE)) {
printk(BIOS_ERR, "coreboot table didn't fit (%lx/%x bytes)\n",
new_table_pointer - table_pointer, MAX_COREBOOT_TABLE_SIZE);
}
printk(BIOS_DEBUG, "coreboot table: %ld bytes.\n",
new_table_pointer - table_pointer);
post_code(0x9e);
/* Print CBMEM sections */
cbmem_list();
return get_lb_mem();
}
struct lb_memory *write_tables(void)
{
unsigned long low_table_start, low_table_end;
unsigned long rom_table_start, rom_table_end;
/* Even if high tables are configured, some tables are copied both to
* the low and the high area, so payloads and OSes don't need to know
* about the high tables.
*/
unsigned long high_table_pointer;
if (!high_tables_base) {
printk(BIOS_ERR, "ERROR: High Tables Base is not set.\n");
// Are there any boards without?
// Stepan thinks we should die() here!
}
printk(BIOS_DEBUG, "High Tables Base is %llx.\n", high_tables_base);
rom_table_start = 0xf0000;
rom_table_end = 0xf0000;
/* Start low addr at 0x500, so we don't run into conflicts with the BDA
* in case our data structures grow beyound 0x400. Only multiboot, GDT
* and the coreboot table use low_tables.
*/
low_table_start = 0;
low_table_end = 0x500;
#if CONFIG_GENERATE_PIRQ_TABLE == 1
#define MAX_PIRQ_TABLE_SIZE (4 * 1024)
post_code(0x9a);
/* This table must be between 0x0f0000 and 0x100000 */
rom_table_end = write_pirq_routing_table(rom_table_end);
rom_table_end = ALIGN(rom_table_end, 1024);
/* And add a high table version for those payloads that
* want to live in the F segment
*/
high_table_pointer = (unsigned long)cbmem_add(CBMEM_ID_PIRQ, MAX_PIRQ_TABLE_SIZE);
if (high_table_pointer) {
unsigned long new_high_table_pointer;
new_high_table_pointer = write_pirq_routing_table(high_table_pointer);
// FIXME make pirq table code intelligent enough to know how
// much space it's going to need.
if (new_high_table_pointer > (high_table_pointer + MAX_PIRQ_TABLE_SIZE)) {
printk(BIOS_ERR, "ERROR: Increase PIRQ size.\n");
}
printk(BIOS_DEBUG, "PIRQ table: %ld bytes.\n",
new_high_table_pointer - high_table_pointer);
}
#endif
#if CONFIG_GENERATE_MP_TABLE == 1
#define MAX_MP_TABLE_SIZE (4 * 1024)
post_code(0x9b);
/* The smp table must be in 0-1K, 639K-640K, or 960K-1M */
rom_table_end = write_smp_table(rom_table_end);
rom_table_end = ALIGN(rom_table_end, 1024);
high_table_pointer = (unsigned long)cbmem_add(CBMEM_ID_MPTABLE, MAX_MP_TABLE_SIZE);
if (high_table_pointer) {
unsigned long new_high_table_pointer;
new_high_table_pointer = write_smp_table(high_table_pointer);
// FIXME make mp table code intelligent enough to know how
// much space it's going to need.
if (new_high_table_pointer > (high_table_pointer + MAX_MP_TABLE_SIZE)) {
printk(BIOS_ERR, "ERROR: Increase MP table size.\n");
}
printk(BIOS_DEBUG, "MP table: %ld bytes.\n",
new_high_table_pointer - high_table_pointer);
}
#endif /* CONFIG_GENERATE_MP_TABLE */
#if CONFIG_GENERATE_ACPI_TABLES == 1
#define MAX_ACPI_SIZE (45 * 1024)
post_code(0x9c);
/* Write ACPI tables to F segment and high tables area */
/* Ok, this is a bit hacky still, because some day we want to have this
* completely dynamic. But right now we are setting fixed sizes.
* It's probably still better than the old high_table_base code because
* now at least we know when we have an overflow in the area.
*
* We want to use 1MB - 64K for Resume backup. We use 512B for TOC and
* 512 byte for GDT, 4K for PIRQ and 4K for MP table and 8KB for the
* coreboot table. This leaves us with 47KB for all of ACPI. Let's see
* how far we get.
*/
high_table_pointer = (unsigned long)cbmem_add(CBMEM_ID_ACPI, MAX_ACPI_SIZE);
if (high_table_pointer) {
unsigned long acpi_start = high_table_pointer;
unsigned long new_high_table_pointer;
rom_table_end = ALIGN(rom_table_end, 16);
new_high_table_pointer = write_acpi_tables(high_table_pointer);
if (new_high_table_pointer > ( high_table_pointer + MAX_ACPI_SIZE)) {
printk(BIOS_ERR, "ERROR: Increase ACPI size\n");
}
printk(BIOS_DEBUG, "ACPI tables: %ld bytes.\n",
new_high_table_pointer - high_table_pointer);
/* Now we need to create a low table copy of the RSDP. */
/* First we look for the high table RSDP */
while (acpi_start < new_high_table_pointer) {
if (memcmp(((acpi_rsdp_t *)acpi_start)->signature, RSDP_SIG, 8) == 0) {
break;
}
acpi_start++;
}
/* Now, if we found the RSDP, we take the RSDT and XSDT pointer
* from it in order to write the low RSDP
*/
if (acpi_start < new_high_table_pointer) {
acpi_rsdp_t *low_rsdp = (acpi_rsdp_t *)rom_table_end,
*high_rsdp = (acpi_rsdp_t *)acpi_start;
acpi_write_rsdp(low_rsdp,
(acpi_rsdt_t *)(high_rsdp->rsdt_address),
(acpi_xsdt_t *)((unsigned long)high_rsdp->xsdt_address));
} else {
printk(BIOS_ERR, "ERROR: Didn't find RSDP in high table.\n");
}
rom_table_end = ALIGN(rom_table_end + sizeof(acpi_rsdp_t), 16);
} else {
rom_table_end = write_acpi_tables(rom_table_end);
rom_table_end = ALIGN(rom_table_end, 1024);
}
#endif
#define MAX_SMBIOS_SIZE 2048
#if CONFIG_GENERATE_SMBIOS_TABLES
high_table_pointer = (unsigned long)cbmem_add(CBMEM_ID_SMBIOS, MAX_SMBIOS_SIZE);
if (high_table_pointer) {
unsigned long new_high_table_pointer;
new_high_table_pointer = smbios_write_tables(high_table_pointer);
rom_table_end = ALIGN(rom_table_end, 16);
memcpy((void *)rom_table_end, (void *)high_table_pointer, sizeof(struct smbios_entry));
rom_table_end += sizeof(struct smbios_entry);
if (new_high_table_pointer > ( high_table_pointer + MAX_SMBIOS_SIZE)) {
printk(BIOS_ERR, "ERROR: Increase SMBIOS size\n");
}
printk(BIOS_DEBUG, "SMBIOS tables: %ld bytes.\n",
new_high_table_pointer - high_table_pointer);
} else {
unsigned long new_rom_table_end = smbios_write_tables(rom_table_end);
printk(BIOS_DEBUG, "SMBIOS size %ld bytes\n", new_rom_table_end - rom_table_end);
rom_table_end = ALIGN(new_rom_table_end, 16);
}
#endif
#define MAX_COREBOOT_TABLE_SIZE (8 * 1024)
post_code(0x9d);
high_table_pointer = (unsigned long)cbmem_add(CBMEM_ID_CBTABLE, MAX_COREBOOT_TABLE_SIZE);
if (high_table_pointer) {
unsigned long new_high_table_pointer;
/* Also put a forwarder entry into 0-4K */
new_high_table_pointer = write_coreboot_table(low_table_start, low_table_end,
high_tables_base, high_table_pointer);
if (new_high_table_pointer > (high_table_pointer +
MAX_COREBOOT_TABLE_SIZE))
printk(BIOS_ERR, "%s: coreboot table didn't fit (%lx)\n",
__func__, new_high_table_pointer -
high_table_pointer);
printk(BIOS_DEBUG, "coreboot table: %ld bytes.\n",
new_high_table_pointer - high_table_pointer);
} else {
/* The coreboot table must be in 0-4K or 960K-1M */
rom_table_end = write_coreboot_table(
low_table_start, low_table_end,
rom_table_start, rom_table_end);
}
post_code(0x9e);
#if CONFIG_HAVE_ACPI_RESUME
/* Let's prepare the ACPI S3 Resume area now already, so we can rely on
* it begin there during reboot time. We don't need the pointer, nor
* the result right now. If it fails, ACPI resume will be disabled.
*/
cbmem_add(CBMEM_ID_RESUME, HIGH_MEMORY_SAVE);
#endif
#if CONFIG_MULTIBOOT
post_code(0x9d);
/* The Multiboot information structure */
write_multiboot_info(rom_table_end);
#endif
// Remove before sending upstream
cbmem_list();
return get_lb_mem();
}